Effects of atmospheric oscillations on the field-aligned ion motions in the polar F-region

Oyama, S.; Nozawa, S.; Buchert, Stephan; Ishii, Mamoru; Watari, Shinichi; Sagawa, E.; Kofman, W.; Lilensten, Jean; Fujii, Ryoichi

doi:10.1007/s00585-000-1154-z

Cited by 5 publications

(2 citation statements)

References 30 publications

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“…In the recovery phase, modeling studies using the National Center for Atmospheric Research Thermosphere Ionosphere General Circulation Model (NCAR‐TIGCM) have found that the neutrals are capable of driving the westward

\overset{E}{true} \times \overset{B}{true}

ionospheric drifts for 5–6 h after the magnetospheric convection declines [ Deng et al , ; Lyons et al , ]. On the observational side, Oyama et al [] used ISR and Fabry‐Perot interferometer (FPI) observations at high latitudes to determine that neutrals drive field‐aligned ion oscillations on a time scale of ∼40 min. Most of these previous works relied heavily on thermospheric models and/or colocated coverage of ISR and FPI instruments at high latitudes.…”

Section: Introductionmentioning

confidence: 99%

Observations of storm time midlatitude ion‐neutral coupling using SuperDARN radars and NATION Fabry‐Perot interferometers

et al. 2015

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Ion drag is known to play an important role in driving neutral thermosphere circulation at auroral latitudes, especially during the main phase of geomagnetic storms. During the recovery phase, the neutrals are known to drive the ions and generate ionospheric electric fields and currents via the disturbance dynamo mechanism. At midlatitudes, the precise interplay between ions and neutrals is less understood largely because of the paucity of measurements that have been available. In this work, we investigate ion‐neutral coupling at middle latitudes using colocated ion drift velocity measurements obtained from Super Dual Auroral Radar Network radars and neutral wind velocity and temperature measurements obtained from the North American Thermosphere Ionosphere Observing Network (NATION) Fabry‐Perot interferometers. We examine one recent storm period on 2–3 October 2013 during both the main phase and late recovery phase. By using ion‐neutral momentum exchange theory and a time‐lagged correlation analysis, we analyze the coupling time scales and dominant driving mechanisms. We observe that during the main phase the neutrals respond to the ion convection on a time scale of ∼84 min which is significantly faster than what would be expected from local ion drag momentum forcing alone. This suggests that other storm time influences are important for driving the neutrals during the main phase, such as Joule heating. During the late recovery phase, the neutrals are observed to drive the ion convection without any significant time delay, consistent with the so‐called “neutral fly wheel effect” or disturbance dynamo persisting well into the late recovery phase.

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\overset{E}{true} \times \overset{B}{true}

Section: Introductionmentioning

confidence: 99%

Observations of storm time midlatitude ion‐neutral coupling using SuperDARN radars and NATION Fabry‐Perot interferometers

et al. 2015

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“…The time constant for momentum transfer from neutral particles to ions is considerably shorter than the EISCAT radar time resolution that is normally longer than a few tens of seconds. This means that neutral wind drag causes observed FA ion oscillations in phase with thermospheric wind variations for oscillate at periods longer than the time constant for neutral‐ion collision effects [ Oyama et al , 2000]. The magnitude of FA ion diffusion velocity caused by plasma pressure gradients and gravity becomes comparable or larger than effects from FA neutral wind drag with increasing height above the F2 peak [ Lilensten and Lathuillere , 1995].…”

Section: Introductionmentioning

confidence: 99%

Field‐aligned ion motions in the polar E‐F transition region: Mean characteristics

Oyama¹

2003

J. Geophys. Res.

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[1] Geomagnetic field-aligned (FA) ion motions in the transition region between E and F regions (from 150 to 250 km; hereafter termed the E-F transition region) in the polar ionosphere are analyzed statistically using data from European Incoherent Scatter (EISCAT) radar from 1987 to 1999. We use all available EISCAT data sets that satisfy the definition of data selection criteria (i.e., 24-hour observation periods beginning at 1200 UT); therefore it has not been feasible to investigate seasonal, solar, and geomagnetical activity dependences. FA ion motions above and below the E-F transition region (250-300 km and 100-150 km, respectively) are also analyzed to compare with lower-altitude ion motions in the E-F transition region. The FA ion velocity that is observed with the EISCAT radar can be written as the sum of the FA ion diffusion velocity and FA component of the thermospheric wind using the ion momentum equation. The main purpose of this paper is to understand quantitatively the relative contributions of ion diffusion and neutral wind on FA ion motions in the E-F transition region. We derive the amplitude and phase of the first three daily harmonics, i.e., the 24-, 12-, and 8-hour periodic oscillations in observed FA ion velocities and estimated FA ion diffusion velocities. The spectral characteristics are determined with a Fast Fourier Transfer (FFT) method after averaging velocity data in 1-hour bins. The amplitude of the 24-hour periodic oscillation is the largest of the three harmonic components for the FA ion velocity as well as FA ion diffusion velocity. While the amplitude of the 24-hour periodic oscillation in FA ion diffusion velocity below 230 km is considerably smaller than the values of the observed FA ion velocities, the amplitude from 230 to 300 km is comparable to that in observed FA ion velocities. From 230 to 300 km the phase of the 24-hour periodic oscillation in FA ion diffusion velocity has about 180°difference from that in the observed FA ion velocity. This spectral analysis results suggest that, in the E-F transition region, FA ion diffusion velocity is not the major contributor to the three harmonic oscillations in the observed FA ion velocities; thus FA component of thermospheric winds or tides prove to be the primary contributor.

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Generation of atmospheric gravity waves associated with auroral activity in the polar F region

Oyama¹,

Ishii²,

Murayama³

et al. 2001

J. Geophys. Res.

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Effects of atmospheric oscillations on the field-aligned ion motions in the polar F-region

Cited by 5 publications

References 30 publications

Observations of storm time midlatitude ion‐neutral coupling using SuperDARN radars and NATION Fabry‐Perot interferometers

Observations of storm time midlatitude ion‐neutral coupling using SuperDARN radars and NATION Fabry‐Perot interferometers

Field‐aligned ion motions in the polar E‐F transition region: Mean characteristics

Generation of atmospheric gravity waves associated with auroral activity in the polar F region

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